Abstract: Synchronized stochastic gradient descent (SGD) optimizers with data
parallelism are widely used in training large-scale deep neural networks.
Although using larger mini-batch sizes can improve the system scalability by
reducing the communication-to-computation ratio, it may hurt the generalization
ability of the models. To this end, we build a highly scalable deep learning
training system for dense GPU clusters with three main contributions: (1) We
propose a mixed-precision training method that significantly improves the
training throughput of a single GPU without losing accuracy. (2) We propose an
optimization approach for extremely large mini-batch size (up to 64k) that can
train CNN models on the ImageNet dataset without losing accuracy. (3) We
propose highly optimized all-reduce algorithms that achieve up to 3x and 11x
speedup on AlexNet and ResNet-50 respectively than NCCL-based training on a
cluster with 1024 Tesla P40 GPUs. On training ResNet-50 with 90 epochs, the
state-of-the-art GPU-based system with 1024 Tesla P100 GPUs spent 15 minutes
and achieved 74.9\% top-1 test accuracy, and another KNL-based system with 2048
Intel KNLs spent 20 minutes and achieved 75.4\% accuracy. Our training system
can achieve 75.8\% top-1 test accuracy in only 6.6 minutes using 2048 Tesla P40
GPUs. When training AlexNet with 95 epochs, our system can achieve 58.7\% top-1
test accuracy within 4 minutes, which also outperforms all other existing
systems.